A stone is dropped from a height h. Its potential energy atfrom a heig

1.	A stone is dropped from a height h. Its potential energy atfrom a height h. Its potential energy at a particular instant isnine times its kinetic energy.When the velocity of the stone becomes double the velocity at that instantwill be the ratio of its new kinetic energy to new potential energy?
Answer» Answer: 2:3 Explanation: Let the distance through which the stone dropped = d Now, it is given that at 'd', potential energy = 9 × KINETIC energy Potential energy when the stone dropped off to 'd' = mg(h-d) where, m is the mass of the stone g is the acceleration due to the gravity also, Now gain in kinetic energy while dropped through distance 'd' = loss in potential energy or Kinetic energy = mgd now USING the relation given in the problem mg(h-d) = 9 × mgd or h - d = 9d or d = h/10 therefore, the kinetic energy for the first case = mgd = mg(h/10) also Kinetic energy = $\frac{1}{2}mv^2$ = mg(h/10) where, v is the velocity and potential energy = 9 × Kinetic energy = 9 × mg(h/10) = (9/10)MGH .....(1) now, for the case 2 velocity of the stone = 2 times the velocity in case 1 or v' = 2v thus, the kinetic energy = $\frac{1}{2}mv'^2$ = $\frac{1}{2}m(2v)^2$ or the kinetic energy = $4\frac{1}{2}mv'^2$ or the kinetic energy = 4×mg(h/10) thus, the potential energy at this point = Initial potential energy - Kinetic energy or the potential energy at this point = mgh - 4×mg(h/10) = (6/10)mgh .......(2) dividing 2 by 1, we have PE₂/PE₁ = $\frac{ (6/10)mgh}{(9/10)mgh}$ or Ratio of NEW potential energy to old = 2:3

A stone is dropped from a height h. Its potential energy atfrom a height h. Its potential energy at a particular instant isnine times its kinetic energy.When the velocity of the stone becomes double the velocity at that instantwill be the ratio of its new kinetic energy to new potential energy?

Answer»

Answer:

2:3

Explanation:

Let the distance through which the stone dropped = d

Now,

it is given that at 'd', potential energy = 9 × KINETIC energy

Potential energy when the stone dropped off to 'd' = mg(h-d)

where, m is the mass of the stone

g is the acceleration due to the gravity

also,

Now gain in kinetic energy while dropped through distance 'd' = loss in potential energy

Kinetic energy = mgd

now USING the relation given in the problem

mg(h-d) = 9 × mgd

h - d = 9d

d = h/10

therefore,

the kinetic energy for the first case = mgd = mg(h/10)

also

Kinetic energy = $\frac{1}{2}mv^2$ = mg(h/10)

where, v is the velocity

and potential energy = 9 × Kinetic energy = 9 × mg(h/10) = (9/10)MGH .....(1)

now,

for the case 2

velocity of the stone = 2 times the velocity in case 1

v' = 2v

thus,

the kinetic energy = $\frac{1}{2}mv'^2$ = $\frac{1}{2}m(2v)^2$

the kinetic energy = $4\frac{1}{2}mv'^2$

the kinetic energy = 4×mg(h/10)

thus,

the potential energy at this point = Initial potential energy - Kinetic energy

the potential energy at this point = mgh - 4×mg(h/10) = (6/10)mgh .......(2)

dividing 2 by 1, we have

PE₂/PE₁ = $\frac{ (6/10)mgh}{(9/10)mgh}$

Ratio of NEW potential energy to old = 2:3

A stone is dropped from a height h. Its potential energy atfrom a height h. Its potential energy at a particular instant isnine times its kinetic energy.When the velocity of the stone becomes double the velocity at that instantwill be the ratio of its new kinetic energy to new potential energy?

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A stone is dropped from a height h. Its potential energy atfrom a height h. Its potential energy at a particular instant isnine times its kinetic energy.When the velocity of the stone becomes double the velocity at that instantwill be the ratio of its new kinetic energy to new potential energy?​

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A stone is dropped from a height h. Its potential energy atfrom a height h. Its potential energy at a particular instant isnine times its kinetic energy.When the velocity of the stone becomes double the velocity at that instantwill be the ratio of its new kinetic energy to new potential energy?